Title :
High temperature electrostrictive ceramics for a Venus ultrasonic rock sampling tool
Author :
Hackenberger, Wesley ; Alberta, Ed ; Rehrig, Paul ; Zhang, Shujun ; Randall, Clive ; Eitel, Richard ; Shrout, Thomas
Author_Institution :
TRS Technol., State College, PA, USA
Abstract :
NASA´s intended mission to Venus (the Venus In-situ Explorer) will require unprecedented advances in robotic technology suited for high temperatures and extreme environments. This paper addresses development of an ultrasonic rock drilling-coring-abrading tool to quickly sample Venus surface material for chemical analysis. The key innovation behind this device is a BiScO3-PbTiO3 piezoelectric ceramic that has been modified to have high resistivity up to 500°C. This material was found to have very good piezoelectric properties to the depoling temperature of 420°C, and at 450°C it functioned as an electrostrictor with an induced piezoelectric coefficient of ∼ 450 pC/N under a 7 kV/cm DC bias.
Keywords :
bismuth compounds; dielectric polarisation; electrical resistivity; electrostriction; lead compounds; piezoceramics; piezoelectricity; planetary rovers; space research; ultrasonic applications; 420 degC; 450 degC; 500 degC; BiScO3-PbTiO3; NASA; Venus In-situ Explorer; Venus surface material; Venus ultrasonic rock sampling tool; chemical analysis; depoling temperature; electrostrictor; high temperature electrostrictive ceramics; piezoelectric ceramic; piezoelectric coefficient; resistivity; robotic technology; ultrasonic rock drilling-coring-abrading tool; Ceramics; Chemical analysis; Chemical technology; Conductivity; Electrostriction; Robots; Sampling methods; Technological innovation; Temperature; Venus;
Conference_Titel :
Applications of Ferroelectrics, 2004. ISAF-04. 2004 14th IEEE International Symposium on
Print_ISBN :
0-7803-8410-5
DOI :
10.1109/ISAF.2004.1418354
